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GPU Accelerated Vessel Segmentation Using Laplacian Eigenmaps Lin Cheng, Hyunsu Cho and Peter A. Yoon Trinity College.

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Presentation on theme: "GPU Accelerated Vessel Segmentation Using Laplacian Eigenmaps Lin Cheng, Hyunsu Cho and Peter A. Yoon Trinity College."— Presentation transcript:

1 GPU Accelerated Vessel Segmentation Using Laplacian Eigenmaps Lin Cheng, Hyunsu Cho and Peter A. Yoon Trinity College

2 Problem Image segmentation Partition pictures of vessels into segments

3 Local info embedded in high dimensional space Project local info onto low-dimensional plane Optimize the projection to preserve essential characteristics Cluster the projected data points into segments [1] Tziakos, Laskaris, and Fotopoulos

4 Segmentation process Build graph of local info Apply Laplace operator Solve optimization problem

5 Build graph of local info Store the resulting graph in a weight matrix Edges reflect variations among different regions (global variation)

6 Apply Laplace operator Form Laplacian matrix L = I – D 1/2 WD 1/2 encoding the Laplace operator. The operator formulates an optimization problem: Projections of well-connected nodes should also be tightly clustered.

7 Solve optimization problem Solutions to eigenvalue problem Ly = λy are optimal solutions If solutions are good, we can detect clusters

8 Characteristics of GPUs Massively parallel – lots of small cores (workers) Good for high-throughput, compute-bound tasks Separate memory space from main memory

9 Strategy: Reduce memory footprint On-GPU memory is limited Reduce memory usage and we can pack in more work into GPU

10 Strategy: Reduce memory footprint Weight matrix generation: Do not store intermediate results More entries can be calculated in parallel; 10x faster

11 Worker allocation

12 Strategy: use Lanczos method We need only a few smallest eigenvalues of L Lanczos method iteratively solve for the eigenvalues needed Takes 1/28 time of conventional method

13 Performance

14 Performance: vs. multicore CPUs CPU: two Intel® Xeon® E5-2620 GPU: one Nvidia Tesla® K20c

15 Acknowledgement Trinity College, Student Research Program Nvidia Corporation, CUDA Teaching Center Program

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